DE1922398B2 - ADJUSTABLE MILLIAMPERESECOND RELAY FOR AN ROYAL DIAGNOSTIC DEVICE - Google Patents

Description

The invention relates to a milliampere second relay According to the preamble of claim 1. Such a mAs relay is known from DT-PS 11 06 430. In the X-ray diagnostic apparatus described there, no stabilization measures are provided, so that both the Römgenröhrenstrom and the X-ray tube voltage from the respective mains voltage depends. A signal is picked up at a resistor, which the mAs relay depends on from the X-ray tube current and thus also from the mains voltage. With this X-ray diagnostic apparatus which can be used, for example, for dental recordings, the difficulty is too overcome to avoid that one and the same set mAs product according to the each line voltage receives different blackened images on the X-ray film

This difficulty occurs when using a mAs relay with larger X-ray diagnostic apparatus, in which means for keeping the X-ray tube current and the high voltage at the X-ray tube constant are not provided. Mains voltage fluctuations do not act in the sense of a change the dose acting on the X-ray film for a given mAs product. You get with these Apparatus always a correct exposure of the X-ray film.

The invention is based on the object of a milliamps relay according to the preamble of claim 1 in such a way that even with a mains voltage deviating from the nominal value the correct blackening of the X-ray film is always achieved without the need for complicated and Elaborate stabilizers for X-ray tube voltage and X-ray tube current were used the.

This object is achieved according to the invention by the in the characterizing part of claim 1 specified training.

The subject of the earlier Di-Patent Ib 39 288 is a mAs relay with a measuring capacitor, which in Depending on the X-ray tube current is charged, as well as a flip-flop, which when a predetermined threshold voltage at the measuring capacitor located in the input circuit of the flip-flop element tips over and thereby provides an impulse to end the recording, in which in the input circuit of the Flip-flop element in series with the measuring capacitor is a DC voltage source, which has a stabilization element, one with a resistor in series Switched Zener diode includes, as well as a variable resistor for setting the desired mAs product. However, the subject matter of this earlier patent does not solve that of the present one Invention underlying task because the voltage superimposed on the capacitor voltage is not in the way depends on the mains voltage that the values of mAs-product and X-ray tube voltage certain radiation dose is kept constant with changing mains voltage.

Further refinements of the invention emerge from the subclaims.

The invention is explained in more detail below with the aid of an exemplary embodiment shown in the drawing explained.

FIG. 1 shows a simplified illustration to explain the exemplary embodiment shown in FIG underlying principle.

In fig. A Schmitt trigger I is indicated, which is controlled by a voltage U applied to its input terminals 2 and is connected to a supply voltage source 3. The control voltage U

is formed by adding the voltage Uy of the voltage source 3 and the voltages Ua and (Λ of two further control voltage sources 4 and 5. The voltage Us should depend on the X-ray tube current and the time. The Schmitt trigger 1 tips over when the control voltage U a reaches a predetermined, constant value U ₀ and outputs a * switch-off signal to a switch-off stage 6, through which the recording is switched off.
The following relationship applies to the control voltage U:

If the voltages U _A and L / j are the same, the recording is switched off when the voltage Ui reaches the value Ua . If, on the other hand, they are different from one another, they are switched off when the voltage (Λ is greater or less than the voltage Uo

By controlling the voltages Lf ₃ and Ua as a function of the mains voltage, with a suitable choice of the voltage curve, one can achieve a shortening in the case of overvoltages and an extension of the recording time in the case of undervoltage compared to the mAs set for the nominal size of the mains voltage. Product resulting recording time. In FIG. 2 shows a circuit arrangement for realizing this principle. From the mains voltage, which is applied to terminals 7, DC voltages are formed via two transformers 8 and 9 and two rectifiers 10 and 11 with filter elements. The DC voltage supplied by the rectifier 10 is stabilized by means of a Zener diode 12, to which a transistor 13 is assigned as an amplifier, in such a way that the DC voltage applied to terminals 14 remains almost constant when the mains voltage changes. The DC voltage supplied by the rectifier ti is stabilized by means of a Zener diode 15 and a transistor 16 as an amplifier, but here a variable resistor 17 is connected in series with the Zener diode 15, so that the course of the DC voltage applied to terminals 18 corresponds to the size of resistor 17 depends on the mains voltage according to a desired function. The voltage applied to terminals 14 corresponds to the voltage L / 4 that is applied to the terminals

18 lying voltage of the voltage L / j in FIG. 1. The voltage L / 5 is supplied by a measuring capacitor 19, which is connected to a charging resistor 20 Resistor 21 is connected, through which the X-ray tube current A flows. The measuring capacitor

19 is therefore charged depending on the X-ray tube current.

In the illustrated embodiment, the resistance 17 shows the course of the difference between the DC voltages applied to terminals 14 and 18, depending on the mains voltage, which is added to the voltage of the measuring capacitor 19 or subtracted from this voltage, see above set that the mAs product selected by the resistor 20 in the sense of keeping the constant Film blackening is reduced when the line voltage is increased and when the line voltage is reduced is increased.

The transistors 13 and 16 can be omitted if Zener diodes are available that are suitable for the direct tapping of the stabilized voltage in the case of the currents occurring. the Stabilized voltages can also be obtained with the help of other electronic switching elements. Instead of a Schmitt trigger, another suitable threshold value element can also be used, which in the case of a predetermined input voltage emits an output pulse. Find use.

Instead of connecting the base of the transistor 16 directly to the resistor 17, the control voltage of the transistor can also be tapped at a voltage divider 22, which is shown in dashed lines in FIG is drawn. In this case the actual value can be de., mAs product by means of the voltage divider 22 compared to that determined by the elements 19, 20, 21 Setpoint changed, d. H. the voltage at which the Schmitt trigger 1 tips over, set and thus the adapted to each patient.

1 sheet of drawings

Claims (5)

Patent claims: 1. Adjustable milliampere second relay for an X-ray diagnostic apparatus with a small setting range the X-ray tube voltage, at which the X-ray tube voltage and the X-ray tube current change according to the fluctuations in the mains voltage, with the milliampere second relay a measuring capacitor, which is charged as a function of the X-ray tube current, and a flip-flop, which when reached a predetermined welding voltage at the measuring capacitor located in the input circuit of the flip-flop element tips over and thereby provides an impulse to end the recording, thereby characterized in that there is a control device (8 to 18) which controls the threshold voltage depending on the mains voltage influenced in such a way that the preset values of MilNamperesecond product and X-ray tube clamping certain radiation dose is kept constant with changing mains voltage. 2. Milliampere second relay according to claim 1, characterized in that the toggle element is a * 5 Schmitt trigger (1) is, and that in its input circuit in series with the measuring capacitor (19) two DC voltage sources (8, 10; 9, 11) that are dependent on the mains voltage and are directed against one another There are voltages whose voltage curve is selected as a function of the mains voltage, determined by the preset values of mAs product and X-ray tube voltage Radiation dose remains constant with changing mains voltage. 3. Milliampere second relay according to one of claims 1 or 2, characterized in that the .Shreshold voltage at which the flip-flop (1) tips over, to adapt the with regard to the respective recording object set m / AS product to different constitutions of the recording object can also be set manually. 4. Milliampere second relay according to one of claims 2 or 3, characterized in that each of the DC voltage sources has a transformer (8 or 9) fed by the mains with a downstream Rectifier (10 or 11) contains and that one of the rectifiers (10) has a stabilizing element (12, 13) for keeping the of it constant supplied DC voltage is assigned. 5. milliamps relay according to claim 4, characterized in that the other Rectifier (11) is assigned a stabilizing element (15, 16) and that to achieve the desired Voltage curve in series with one of the two rectifiers (11) assigned to a part a resistor (17) is connected to the Zener diode (15) forming the corresponding stabilizing element, whose value can be changed for the changeable setting of the mAs product.